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Dark Matter, the Higgs Mass, and String Phenomenology

Dark Matter, the Higgs Mass, and String Phenomenology. StringPheno 2012 Shanta de Alwis University of Colorado. Based on 1202.1546 and 1203.5796 (with K. Givens). Necessary conditions for string pheno.

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Dark Matter, the Higgs Mass, and String Phenomenology

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  1. Dark Matter, the Higgs Mass, and String Phenomenology StringPheno 2012 Shanta de Alwis University of Colorado Based on 1202.1546 and 1203.5796 (with K. Givens)

  2. Necessary conditions for string pheno • The model must have enough freedom to have a tunable CC – by choice of fluxes for example – currently the only available mechanism for getting a sufficiently dense ‘discretuum”. • All the moduli should be stabilized at a SUSY breaking minimum with the latter scale being low enough to allow a meaningful phenomenology. Even if the exact mechanism for finding a minimum with CC at 10^-3 eV scale is not known the theoretical predictions should be insensitive to the tuning of the CC. • Phenomenological and Cosmological constraints should be satisfied. • The output should not depend strongly on the details of the SM construction – the only meaningful predictions are generic ones. Such details can easily be swamped by the tuning of the CC. • LVS phenomenology satisfies all these criteria – though a concrete construction of the MSSM (without chiral exotics) is not yet available • In the heterotic case MSSM like models exist – Moduli stabilization and tuning of CC not so clear.

  3. The CC and ‘predictivity’

  4. Top down inputs Begin with the low energy limit of IIB string theory compactified on a Calabi-Yau Orientifold chosen to be of the “Swiss Cheese” type BBCQ Leads to LVS – only known moduli stabilization scenario with SUSY breaking minimum Assume MSSM located on D3 branes at a singularity. Alternatively on a stack of magnetized D7 branes wrapping a 4-cycle

  5. General SUGRA framework At the two derivative level the form of the action is determined by these.

  6. SUGRA Inputs

  7. Potential

  8. Requirements for SUSY Breaking Need a Minimum with The second condition is CC=0. Involves fine tuning (after quantum corrections). Even if not satisfied exactly the phenomenological conclusions must NOT be sensitive to this constraint! i.e. This SUSY breaking must result in non-zero scalar and gaugino masses whose values are not very sensitive to the value of the CC.

  9. Validity of SUGRA approximation In String theory 4D SUGRA comes after integrating out massive states. Derivative expansion is actually a superderivative expansion in SUSY M lowest integrated out scale Total # fixed is For validity of expansion generically: String example:

  10. GMSB: SUSY Breaking Field X. Messenger scale Generically SUSY breaking scale small/two derivative expansion valid i.e. If M is highest scale integrated out However in LVS models where couplings are suppressed this restriction may be too strong – currently being investigated with FQ

  11. Expansion in MSSM Fields Soni-Weldon Ibanez-Luest Kap-Louis Brignole et al. NOTE: Above formulae valid at quantum level with appropriate change in K. Eg: −>

  12. Weyl Transformations

  13. Weyl Anomaly Effects KL Konishi NSVZ A-H,M

  14. Different versions of LVS • mSUGRA like – assumes moduli mixing. Depends on pushing Field Theoretic arguments beyond string scale • LARGE VS. Really Really want to see strings at LHC! Need internal volume ~ 10^30 in string units. Need to introduce explicit SUSY breaking in 4D such as a Dbar brane. • MSSM on magnetized D7 branes wrapping a 4-cycle – realizes a partially sequestered phenomenology CAQS, CMV • MSSM on D3 branes at a singularity – leads to sequestered phenomenology BCKMQ, deA

  15. Status of first two scenarios is theoretically unclear • Will only consider the third and fourth • The third has cosmological problems like mSUGRA • Only version of LVS which may survive both theoretical and phenomenological constraints is the last one. • Unfortunately this leads in large part to an unobservable (at the LHC) SUSY partners!

  16. Classical Results To obtain LVS need to choose “Swss Cheese’ type manifold and include alpha’ corrections

  17. Classical Results Minimize and find F-terms:

  18. FCNC issues D7 case First investigate constraints for MSSM on D7 brane wrapping a magnetized 4-cycle. Matter from Wilson line moduli moduli Jockers-Louis

  19. FCNC suppression requires Even with relatively high values of gravitino and soft masses We need extremely large values of the volume > This actually leads to < TeV scale soft masses if we can take W of O(1) (√F/M?). No cosmological gravitino problem but serious modulus problem.

  20. The brane field fluctuations may also be identified as matter JL Metric from holomorphic dilaton In original LVS minimum Uplift needs to give a CC =0

  21. The gaugino mass controlled by small cycle wrapped by D7 branes Get mSUGRA scenario in the second case! Cosmological gravitino/moduli problems require m_3/2> 10 TeV To avoid cosmological modulus problem since need gravitinos at 100TeV scale Largest is 2π so this gives gaugino masses > 5 TeV Gives a viable phenomenology but little hierarchy fine tuning at 1/10^6 level!

  22. FCNC in D3 case BCKMQ deA However the harmonic form of small cycle from blowing up a singularity expected to fall off as R^-6 so we then end up with However the situation is changed completely by Weyl anomaly generated gaugino masses in this case.

  23. inoAMSB = Weyl anomaly+ Gaugino Mediation Leads to one loop order gaugino masses: Scalar masses generated by RG Integrates to (with high scale soft mass suppressed)

  24. In this case the quantum generated soft mass from inoAMSB is In contrast to the classical soft mass The FCNC constraint is cosiderably softened to Hence we get

  25. Non Perturbative FCNC effects Berg et al

  26. Phenomenology of inoAMSB Collaborators : H. Baer, K. Givens, S. Rajagopalan and S. Summy Boundary conditions at High (GUT?) scale: Also to a good approximation in these models Initial values for RG evolution. μ and Bμ terms depend on uplift. Take phenomenological approach: values determined by E-W symmetry breaking. B parameter traded for μ fixed by Z - mass Parameter space

  27. Output • A two parameter (+ sign of μ) phenomenology • All SUSY breaking soft terms essentially determined by gravitino mass and tanβ • Avoiding FCNC leads to CYO Vol >10^4 in string units hence avoiding modulus problem implies 500TeV <m_3/2 • This gives a Higgs mass in 122-126 GeV range – m_3/2=500TeV tanβ=40 gives M_Higgs =124GeV. • For m_3/2=500TeV LSP is around 1.4TeV! No SUSY partners will be seen at LHC even with 100fb^-1 of data.

  28. Main Prediction If this line of reasoning is correct then the LHC will not see superpartners! Certainly consistent with current data!! Obviously an argument for resurrecting the SSC!!!

  29. Summary • LVS gives either mSUGRA like or inoAMSB like phenomenology • mSUGRA like seems to be ruled out by Cosmology • inoAMSB may survive (assuming modulus problem is OK – thermal inflation? • In this case correlation between dark matter density and Higgs mass but if former saturated Higgs mass in right range but no SUSY will be seen at LHC!

  30. Is there a Way out? • Assume that the string construction gives the NMSSM rather than the MSSM. Don’t expect much change besides additional scalar state to stabilize. • So if TeV scale SUSY particles are found the whole construction will be vitiated. • We would need different types of SUSY breaking and moduli stabilization mechanisms within string theory –perhaps heterotic strings.

  31. Acknowledgements • Fernado Quevedo and Joe Conlon for discussions on LVS etc. • Howie Baer, Kevin Givens, Summy Heaya, Shibi Rajagopalan for collaboration on phenomenology of inoAMSB • DOE grant DE-FG02-91-ER-40672 for support

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